US20190179133A1 - Color wheel for projector - Google Patents
Color wheel for projector Download PDFInfo
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- US20190179133A1 US20190179133A1 US16/214,144 US201816214144A US2019179133A1 US 20190179133 A1 US20190179133 A1 US 20190179133A1 US 201816214144 A US201816214144 A US 201816214144A US 2019179133 A1 US2019179133 A1 US 2019179133A1
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- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/007—Optical devices or arrangements for the control of light using movable or deformable optical elements the movable or deformable optical element controlling the colour, i.e. a spectral characteristic, of the light
- G02B26/008—Optical devices or arrangements for the control of light using movable or deformable optical elements the movable or deformable optical element controlling the colour, i.e. a spectral characteristic, of the light in the form of devices for effecting sequential colour changes, e.g. colour wheels
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03B—APPARATUS OR ARRANGEMENTS FOR TAKING PHOTOGRAPHS OR FOR PROJECTING OR VIEWING THEM; APPARATUS OR ARRANGEMENTS EMPLOYING ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ACCESSORIES THEREFOR
- G03B21/00—Projectors or projection-type viewers; Accessories therefor
- G03B21/14—Details
- G03B21/20—Lamp housings
- G03B21/2006—Lamp housings characterised by the light source
- G03B21/2033—LED or laser light sources
- G03B21/204—LED or laser light sources using secondary light emission, e.g. luminescence or fluorescence
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Abstract
Description
- The present invention relates to a color wheel, and more particularly to a color wheel for a projector.
- For projection systems using a single digital light processing (DLP) chip, the light splitting therefor is based on time divisions and is usually performed by a color wheel. If the color wheel includes only three filter blocks corresponding to red, green, and blue respectively, red light, green light, and blue light are individually produced once in one turn of the color wheel, which probably makes projected images with defects (e.g. rainbow artifact). For this issue, a common solution is to increase the quantity of the filter blocks of the color wheel, e.g. from 3 to 6, i.e. the red filter block, the green filter block, and the blue filter block are arranged repeatedly. For this case, red light, green light, and blue light are individually produced twice in one turn of the color wheel, which can reduce the effect of rainbow artifact in the projected images. However, in this solution of repeating the filter blocks, because the filter blocks increase in quantity, the production difficulty and cost of the color wheel will increase. Furthermore, a light source will face two filter blocks in different colors at junctions or spoke transition areas of any two adjacent filter blocks, resulting in that the color of the light from the light source through the color wheel is impure. Thus, when the filter blocks increase in quantity, the spoke transition areas increase in quantity resulting in reduction of color light output or color brightness.
- The present invention provides a color wheel for a projector. The arrangement order for color blocks of the color wheel is designed so as to decrease the quantity of the actual filter blocks and the quantity of spoke transition areas on the color wheel as well, which can improve the color brightness of the projector.
- A color wheel for a projector of an embodiment according to the invention includes X color blocks and Y filter blocks. The X color blocks are defined to be arranged in an annular direction by repeating (N-1) times. Light permeability characteristics of the X color blocks are distinct from one another. The X color blocks correspond to X light colors respectively. The X color blocks are substantially equal in area. X is an integer greater than or equal to 3. N is an integer greater than or equal to 2. Furthermore, the Y filter blocks are formed of the X color blocks. The Y filter blocks correspond to the X light colors. Therein, one of the Y filter blocks is formed by adjacent two of the color blocks having the same light permeability characteristic. In another aspect, in the color wheel, the Y physical filter blocks are arranged in a ring. The color blocks are defined on the Y filter blocks. Therein, the color blocks are grouped into N sets of color blocks. Each set includes X color blocks. In practice, one set of color blocks (i.e. the X color blocks) corresponds to a projection period (i.e. for projecting a frame of color image). Because one of the filter block is formed by two color blocks that have the same light permeability characteristic, this filter block corresponds to two adjacent projection periods; that is, no physical junction of two filter blocks exists at the junction of the two adjacent projection periods. In other words, this filter block eliminates a spoke transition area, which can improve the color brightness of the projector in comparison with the prior art.
- A color wheel for a projector of another embodiment according to the invention includes Y filter blocks and N central angles. The Y filter blocks are arranged in an annular direction. The Y filter blocks correspond to X light colors. The Y filter blocks are defined to be formed of X color blocks. The light permeability characteristics of the X color blocks are distinct from one another. The X color blocks correspond to the X light colors respectively. The X color blocks are substantially equal in area. X is an integer greater than or equal to 3. The N central angles are equal. Each central angle corresponds to the X color blocks. N is an integer greater than or equal to 2. Therein, a first adjacent edge of any adjacent two of the central angles and a second adjacent edge of any adjacent two of the Y filter blocks are staggered. In another aspect, in the color wheel, the color blocks are defined on the physical Y filter blocks. Therein, the color blocks are grouped into N sets of color blocks. Each set includes X color blocks. In practice, one central angle (or one set of color blocks, i.e. the X color blocks) corresponds to a projection period (i.e. for projecting a frame of color image). Because the first adjacent edge of any adjacent two of the central angles and the second adjacent edge of any adjacent two of the Y filter blocks are staggered, no physical junction of two filter blocks exists at the junction of any adjacent two of the projection periods. In other words, the color wheel eliminates N spoke transition areas, which can improve the color brightness of the projector in comparison with the prior art.
- These and other objectives of the present invention will no doubt become obvious to those of ordinary skill in the art after reading the following detailed description of the preferred embodiment that is illustrated in the various figures and drawings.
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FIG. 1 is a schematic diagram illustrating a color wheel according to an embodiment. -
FIG. 2 is a schematic diagram illustrating a common color wheel. -
FIG. 3 is a schematic diagram illustrating a color wheel according to another embodiment. -
FIG. 4 is a schematic diagram illustrating a color wheel according to another embodiment. -
FIG. 5 is a schematic diagram illustrating a color wheel according to another embodiment. -
FIG. 6 is a schematic diagram illustrating a color wheel according to another embodiment. -
FIG. 7 is a schematic diagram illustrating a color wheel according to another embodiment. - Please refer to
FIG. 1 . Acolor wheel 1 according to an embodiment includes fourfilter blocks annular direction 10 a (which is defined relative to the rotation axis of thecolor wheel 1 and is indicated by an arrow in the figure; therein, the rotation axis is indicated by a cross mark in the figure). The four physical filter blocks 11-14 correspond to three light colors (i.e. red light, green light, and blue light). Therein, the filter blocks 11-14 correspond to red light, green light, blue light, and green light respectively. The four filter blocks 11-14 are defined to be formed of three color blocks (i.e. a red color block R, a green color block G, and a blue color block B, which are shown by frames in dashed lines inFIG. 1 and are labeled R, G, B respectively; therein, the frames are shrunk for convenience of identifying the color blocks). The light permeability characteristics of the three color blocks R, G and B are distinct from one another. The three color blocks R, G and B correspond to the three light colors respectively (i.e. corresponding to red light, green light, and blue light respectively). In practice, based on their light permeability characteristics, the three color blocks R, G and B can transmit red light, green light, and blue light respectively (e.g. by filtering white light emitted by a light source). The three color blocks R, G and B are equal in area. In the embodiment, thefilter block 11 is formed by two red color blocks R. Thefilter block 12 is formed by one green color block G. Thefilter block 13 is formed by two blue color blocks B. Thefilter block 14 is formed by one green color block G. In another aspect, thecolor wheel 1 can be regarded as being provided with three color blocks R, G and B which are defined to be arranged in anannular direction 10 a by repeating 1 time (or repeating (N-1) times; therein N is equal 2). Therein, for the first arrangement, the three color block R, G and B are arranged by a color order of R, G and B (assigned as a first color order) in theannular direction 10 a. For the second arrangement, the three color block R, G and B are arranged by a color order of B, G and R (assigned as a second color order) in theannular direction 10 a. In other words, the three color blocks R, G and B are arranged in theannular direction 10 a by the first color order and the second color order respectively and successively. The first color order is different from the second color order. Adjacent two of the color blocks (e.g. the upper two red color blocks R, or the lower two blue color blocks inFIG. 1 ) which are arranged by the first color order and the second color order respectively have the same light permeability characteristic. - Furthermore, in the embodiment, the
color wheel 1 includes two central angles CA11 and CA12 (relative to the rotation axis; or N central angles, therein N being equal to 2) . The central angles CA11 and CA12 are equal. Each of the central angle CA11 and CA12 corresponds to the three color blocks R, G and B (i.e. covering the three color blocks R, G and B). In the view point ofFIG. 1 , the central angles CA11 and CA12 adjoin at the upper and lower locations in the figure. Therein, an adjacent edge CA1 a of the central angles CA11 and CA12 at the upper portion of the figure and an adjacent edge of any two adjacent filter blocks 11-14 (e.g. anadjacent edge 11 a of the filter blocks 11 and 12) are staggered. An adjacent edge CA1 b of the central angles CA11 and CA12 at the lower portion of the figure and an adjacent edge of any two adjacent filter blocks 11-14 (e.g. anadjacent edge 12 a of the filter blocks 12 and 13) are staggered. In another aspect, in thecolor wheel 1, thefilter block 11 is formed by two color blocks (i.e. the red color blocks R) which have the same light permeability characteristic, and corresponds to the adjacent edge CA1 a. Thefilter block 13 is formed by two color blocks (i.e. the blue color blocks B) which have the same light permeability characteristic, and corresponds to the adjacent edge CA1 b. - In practice, the
color wheel 1 can be used in a 3-color projection system. Thecolor wheel 1 can transmit light in three different colors by use of the filter blocks in each of the central angle CA11 and CA12, so each of the central angles CA11 and CA12 corresponds to one projection period (used for projecting a frame of color image). Although the arrangement orders of the three color blocks R, G and B within the central angles CA11 and CA12 are different, it is practicable to control a digital micromirror device (DMD) of the projection system to operate in coordination with the time sequence of light colors provided by thecolor wheel 1, so as to overcome the difference between the arrangement orders. In addition, for a common color wheel (as shown byFIG. 2 ), its filter blocks (labeled R, G, B in the figure) are repeatedly arranged by the same arrangement order. Compared with thecolor wheel 1, the common color wheel (labeled corresponding central angles CA11 and CA12 inFIG. 2 for convenience of comparison) has a spoke transition area between any adjacent two filter block within each of central angles CA11 and CA12. Furthermore, because the two adjacent filter blocks in the central angles CA11 and CA12 respectively are different, a spoke transition area is formed between the two adjacent filter blocks at the junction of the central angles CA11 and CA12. In theabove color wheel 1, the adjacent edges CA1 a and CA1 b of the central angles CA11 and CA12 do not align with any junctions of physical filter blocks, so no spoke transition area will be formed at the junctions of the central angles CA11 and CA12; thereby, the color brightness of the projected images can be improved. In addition, in practice, thecolor wheel 1 can be modified to be acolor wheel 2 as shown byFIG. 3 . In thecolor wheel 2, the portion thereof corresponding to thefilter block 11 of thecolor wheel 1 is divided into filter blocks 21 a and 21 b (formed by a red color block R and a green color block G respectively). Thefilter block 14 of thecolor wheel 2 is formed by a red color block R relative to thecolor wheel 1. In thecolor wheel 2, the lower adjacent edge CA1 b of the central angles CA11 and CA12 is still not aligned with a junction of physical filter block, which still has the effect of improving the color brightness of the projected images. In another aspect, in thecolor wheel 2, the three color blocks R, G and B are also arranged twice (e.g. N=2). The color block at an end of the first time (i.e. the (N-1)th time) and the color block at a start of the second time (i.e. the (N)th time) have the same light permeability characteristic (i.e. that of blue color block B), which is also applicable to thecolor wheel 1. Furthermore, as shown byFIG. 1 , in the embodiment, the adjacent edge CA1 a is located within thecorresponding filter block 11 and further at a middle line of thefilter block 11. Furthermore, the adjacent edge CA1 b is located within thecorresponding filter block 13 and further at a middle line of thefilter block 13. However, in practice, it is practicable to make different setting according to actual projection conditions (e.g. the adjacent edges CA1 a and CA1 b not being located at the middle lines of the filter blocks 11 and 13). - Furthermore, in the
color wheel 1, within each of the central angles CA11 and CA12, each of the filter blocks 11-14 has the same arc length along theannular direction 10 a. For example, within the central angle CA11, the red color block R of thefilter block 11, the filter block 12 (i.e. one green color block G), and the blue color block B of thefilter block 13 correspond to the same central angle in degrees and the same arc length. However, it is not limited thereto in practice. For example, within the central angle CA11, the central angle and arc length corresponding to the filter block 12 (i.e. one green color block G) are larger than the central angle and arc length corresponding to the red color block R of thefilter block 11 or the blue color block B of thefilter block 13. Furthermore, in the embodiment, for each light color, the filter blocks corresponding to the light color have the same arc length along theannular direction 10 a in each central angle CA11 and CA12. For example, for green light, the central angle and arc length corresponding to thefilter block 12 in the central angle CA11 are the same as the central angle and arc length corresponding to thefilter block 14 of the central angle CA12 respectively. However, in practice, it is practicable to make different setting according to actual projection conditions (e.g. the corresponding arc lengths are not equal). - Furthermore, in the embodiment, three successive filter blocks (e.g. the filter blocks 11-13) can be defined as a primary area and a secondary area. The primary area is a first filter block (i.e. the filter block 11). The secondary area includes a second filter block (i.e. the filter block 12) and a third filter block (i.e. the filter block 13). The second filter block is smaller than the first filter block in area. The first filter block is twice the second filter block in area. For another example, three successive filter blocks 12-14 can be defined as a primary area and a secondary area. The primary area is a first filter block (i.e. the filter block 13). The secondary area includes a second filter block (i.e. the filter block 12) and a third filter block (i.e. the filter block 14). The second filter block is smaller than the first filter block. The first filter block is twice the second filter block.
- In addition, in the embodiment, in logic, the
color wheel 1 has Y physical filter blocks. Thecolor wheel 1 thereon defines X color blocks (corresponding X light colors respectively) which are arranged in theannular direction 10 a by repeating (N-1) times. Each filter block is formed by one or more of one of the X defined color blocks. Therefore, thecolor wheel 1 can provide light of X light colors in each arrangement. Therein, X, N and Y satisfy the following equation: (X×N)−N=Y. In the embodiment, X is equal to 3, N is equal to 2, and Y is equal to 4. - Please refer to
FIG. 4 . Acolor wheel 3 according to another embodiment includes six filter blocks 31, 32, 33, 34, 35 and 36, which are a red filter block, a green filter block, a blue filter block, a red filter block, a green filter block, and a blue filter block respectively arranged an annular direction 30 a (defined relative to the rotation axis of thecolor wheel 3 and indicated by an arrow in the figure; therein, the rotation axis of thecolor wheel 3 is indicated by a cross mark in the figure). The six physical filter blocks 31-36 correspond to three light colors (i.e. red light, green light, and blue light). Therein, the filter blocks 31-36 correspond to red light, green light, blue light, red light, green light, and blue light respectively. The six filter blocks 31-36 are formed of three color blocks (i.e. a red color block R, a green color block G, and a blue color block B, which are shown by frames in dashed lines inFIG. 4 and are labeled R, G, B respectively; therein, the frames are shrunk for convenience of identifying the color blocks). The light permeability characteristics of the three color blocks R, G and B are distinct from one another. The three color blocks R, G and B correspond to the three light colors respectively (i.e. corresponding to red light, green light, and blue light respectively). In practice, based on their light permeability characteristics, the three color blocks R, G and B can transmit red light, green light, and blue light respectively (e.g. by filtering white light emitted by a light source). The three color blocks R, G and B are equal in area. In the embodiment, thefilter block 31 is formed by two red color blocks R. Thefilter block 32 is formed by one green color block G. Thefilter block 33 is formed by two blue color blocks B. Thefilter block 34 is formed by one red color block R. Thefilter block 35 is formed by two green color blocks G. Thefilter block 36 is formed by one blue color block B. Furthermore, in the embodiment, thecolor wheel 3 includes three central angles CA31, CA32 and CA33 (relative to the rotation axis). The central angles CA31, CA32 and CA33 are equal. Each of the central angles CA31, CA32 and CA33 covers the three color blocks R, G and B. - In the embodiment, the arrangement logic of the filter blocks of the
color wheel 3 is similar to that of thecolor wheel 1. A difference therebetween is that the three color blocks R, G and B are arranged by three times on thecolor wheel 3. The other structural features of thecolor wheel 3 are the same as thecolor wheel 1. For example, the adjacent edges of the central angles CA31, CA32 and CA33 (i.e. the junctions thereof) and the adjacent edge of any two adjacent filter blocks 31-36 (i.e. the junctions thereof) are staggered. For example, the adjacent edge CA3 a of the central angles CA31 and CA33 does not align with the junction of the filter blocks 31 and 32 and the junction of the filter blocks 31 and 36. The adjacent edge CA3 b of the central angles CA31 and CA32 does not align with the junction of the filter blocks 32 and 33 and the junction of the filter blocks 33 and 34. The adjacent edge CA3 c of the central angles CA32 and CA33 does not align with the junction of the filter blocks 34 and 35 and the junction of the filter blocks 35 and 36. For other descriptions about thecolor wheel 3, please refer to the relevant descriptions of thecolor wheel 1 and variations thereof, which will not be described in addition. Furthermore, in the embodiment, in logic, thecolor wheel 3 has Y physical filter blocks. Thecolor wheel 3 thereon defines X color blocks (corresponding X light colors respectively) which are arranged in the annular direction 30 a by repeating (N-1) times. Each filter block is formed by one or more of one of the X defined color blocks. Therefore, thecolor wheel 3 can provide light of X light colors in each arrangement. Therein, X is equal to 3, N is equal to 3, Y is equal to 6, and X, N and Y satisfy the following equation: (X×N)−N=Y. - Please refer to
FIG. 5 . A color wheel 4 according to another embodiment includes six filter blocks 41, 42, 43, 44, 45 and 46, which are a red filter block, a green filter block, a white filter block, a blue filter block, a green filter block, and a white filter block respectively arranged an annular direction 40 a (defined relative to the rotation axis of the color wheel 4 and indicated by an arrow in the figure; therein, the rotation axis of the color wheel 4 is indicated by a cross mark in the figure). In practice, the color wheel 4 can be realized by a transparent circle plate, on which different filter films are attached. Therein, the white filter block can be realized by the corresponding area without attaching any filter film thereon; that is, the corresponding area will not filter light in principle. The six physical filter blocks 41-46 correspond to four light colors (i.e. red light, green light, blue light, and white light). Therein, the filter blocks 41-46 correspond to red light, green light, white light, blue light, green light, and white light respectively. The six filter blocks 41-46 are formed of four color blocks (i.e. a red color block R, a green color block G, a blue color block B, and a white color block W, which are shown by frames in dashed lines inFIG. 5 and are labeled R, G, B, W respectively; therein, the frames are shrunk for convenience of identifying the color blocks). The light permeability characteristics of the four color blocks R, G, B and W are distinct from one another. The four color blocks R, G, B and W correspond to the four light colors respectively (i.e. corresponding to red light, green light, blue light, and white light respectively). In practice, based on their light permeability characteristics, the four color blocks R, G, B and W can transmit red light, green light, blue light, and white light (i.e. without filtering for obtaining the white light directly) respectively (e.g. by filtering white light emitted by a light source). The four color blocks R, G, B and W are equal in area. In the embodiment, thefilter block 41 is formed by two red color blocks R. Thefilter block 42 is formed by one green color block G. Thefilter block 43 is formed by one white color block W. Thefilter block 44 is formed by two blue color blocks B. Thefilter block 45 is formed by one green color block G. Thefilter block 46 is formed by two white color blocks W. Furthermore, in the embodiment, the color wheel 4 includes two central angles CA41 and CA42 (relative to the rotation axis). The central angles CA41 and CA42 are equal. Each of the central angles CA41 and CA42 covers the four color blocks R, G, B and W. - In the embodiment, the arrangement logic of the filter blocks of the color wheel 4 is similar to that of the
color wheel 1. A difference therebetween is that the four color blocks R, G, B and W are arranged on the color wheel 4. The other structural features of the color wheel 4 are the same as thecolor wheel 1. For example, the adjacent edges of the central angles CA41 and CA42 (i.e. the junctions thereof) and the adjacent edge of any two adjacent filter blocks 41-46 (i.e. the junctions thereof) are staggered. For example, the adjacent edge CA4 a of the central angles CA41 and CA42 does not align with the junction of the filter blocks 41 and 42 and the junction of the filter blocks 41 and 46. The adjacent edge CA4 b of the central angles CA41 and CA42 does not align with the junction of the filter blocks 43 and 44 and the junction of the filter blocks 44 and 45. For other descriptions about the color wheel 4, please refer to the relevant descriptions of thecolor wheel 1 and variations thereof, which will not be described in addition. Furthermore, in the embodiment, in logic, the color wheel 4 has Y physical filter blocks. The color wheel 4 thereon defines X color blocks (corresponding X light colors respectively) which are arranged in the annular direction 40 a by repeating (N-1) times. Each filter block is formed by one or more of one of the X defined color blocks. Therefore, the color wheel 4 can provide light of X light colors in each arrangement. Therein, X is equal to 4, N is equal to 2, Y is equal to 6, and X, N and Y satisfy the following equation: (X×N)−N=Y. - Please refer to
FIG. 6 . A color wheel 5 according to another embodiment includes eight filter blocks 51, 52, 53, 54, 55, 56, 57 and 58, which are a red filter block, a green filter block, a blue filter block, a yellow filter block, a white filter block, a yellow filter block, a green filter block, and a blue filter block respectively arranged an annular direction 50 a (defined relative to the rotation axis of the color wheel 5 and indicated by an arrow in the figure; therein, the rotation axis of the color wheel 5 is indicated by a cross mark in the figure). In practice, the color wheel 5 can be realized by a transparent circle plate, on which different filter films are attached. Therein, the white filter block can be realized by the corresponding area without attaching any filter film thereon; that is, the corresponding area will not filter light in principle. The eight physical filter blocks 51-58 correspond to five light colors (i.e. red light, green light, blue light, yellow light, and white light). Therein, the filter blocks 51-58 correspond to red light, green light, blue light, yellow light, white light, yellow light, green light, and blue light respectively. The eight filter blocks 51-58 are formed of five color blocks (i.e. a red color block R, a green color block G, a blue color block B, yellow color block Y and a white color block W, which are shown by frames in dashed lines inFIG. 6 and are labeled R, G, B, Y, W respectively; therein, the frames are shrunk for convenience of identifying the color blocks). The light permeability characteristics of the five color blocks R, G, B, Y and W are distinct from one another. The five color blocks R, G, B, Y and W correspond to the five light colors respectively (i.e. corresponding to red light, green light, blue light, yellow light, and white light respectively). In practice, based on their light permeability characteristics, the five color blocks R, G, B, Y and W can transmit red light, green light, blue light, yellow light, and white light (i.e. without filtering for obtaining the white light directly) respectively (e.g. by filtering white light emitted by a light source). The five color blocks R, G, B, Y and W are equal in area. In the embodiment, thefilter block 51 is formed by two red color blocks R. Thefilter block 52 is formed by one green color block G. Thefilter block 53 is formed by one blue color block B. Thefilter block 54 is formed by one yellow color block Y. Thefilter block 55 is formed by two white color blocks W. The filter block 56 is formed by one yellow color block Y. Thefilter block 57 is formed by one green color block G. Thefilter block 58 is formed by one blue color block B. Furthermore, in the embodiment, the color wheel 5 includes two central angles CA51 and CA52 (relative to the rotation axis). The central angles CA51 and CA52 are equal. Each of the central angles CA51 and CA52 covers the five color blocks R, G, B, Y and W. - In the embodiment, the arrangement logic of the filter blocks of the color wheel 5 is similar to that of the
color wheel 1. A difference therebetween is that the five color blocks R, G, B, Y and W are arranged on the color wheel 5. The other structural features of the color wheel 5 are the same as thecolor wheel 1. For example, the adjacent edges of the central angles CA51 and CA52 (i.e. the junctions thereof) and the adjacent edge of any two adjacent filter blocks 51-58 (i.e. the junctions thereof) are staggered. For example, the adjacent edge CA5 a of the central angles CA51 and CA52 does not align with the junction of the filter blocks 51 and 52 and the junction of the filter blocks 51 and 58. The adjacent edge CA5 b of the central angles CA51 and CA52 does not align with the junction of the filter blocks 54 and 55 and the junction of the filter blocks 55 and 56. For other descriptions about the color wheel 5, please refer to the relevant descriptions of thecolor wheel 1 and variations thereof, which will not be described in addition. Furthermore, in the embodiment, in logic, the color wheel 5 has Y physical filter blocks. The color wheel 5 thereon defines X color blocks (corresponding X light colors respectively) which are arranged in the annular direction 50 a by repeating (N-1) times. Each filter block is formed by one or more of one of the X defined color blocks. Therefore, the color wheel 5 can provide light of X light colors in each arrangement. Therein, X is equal to 5, N is equal to 2, Y is equal to 8, and X, N and Y satisfy the following equation: (X×N)−N=Y. - Please refer to
FIG. 7 . Acolor wheel 6 according to another embodiment includes eight filter blocks 61, 62, 63, 64, 65, 66, 67 and 68, which are a red filter block, a green filter block, a blue filter block, a green filter block, a red filter block, a green filter block, a blue filter block, and a green filter block respectively arranged an annular direction 60 a (defined relative to the rotation axis of thecolor wheel 6 and indicated by an arrow in the figure; therein, the rotation axis of thecolor wheel 6 is indicated by a cross mark in the figure). The eight physical filter blocks 61-68 correspond to three light colors (i.e. red light, green light, and blue light). Therein, the filter blocks 61-68 correspond to red light, green light, blue light, green light, red light, green light, blue light, and green light respectively. The eight filter blocks 61-68 are formed of three color blocks (i.e. a red color block R, a green color block G, and a blue color block B, which are shown by frames in dashed lines inFIG. 7 and are labeled R, G and B respectively; therein, the frames are shrunk for convenience of identifying the color blocks). The light permeability characteristics of the five color blocks R, G and B are distinct from one another. The three color blocks R, G and B correspond to the three light colors respectively (i.e. corresponding to red light, green light, and blue light respectively). In practice, based on their light permeability characteristics, the three color blocks R, G and B can transmit red light, green light, and blue light respectively (e.g. by filtering white light emitted by a light source). The three color blocks R, G and B are equal in area. In the embodiment, thefilter block 61 is formed by two red color blocks R. Thefilter block 62 is formed by one green color block G. Thefilter block 63 is formed by one blue color block B. Thefilter block 64 is formed by one green color block G. Thefilter block 65 is formed by two red color blocks R. Thefilter block 66 is formed by one green color block G. Thefilter block 67 is formed by one blue color block B. Thefilter block 68 is formed by one green color block G. Furthermore, in the embodiment, thecolor wheel 6 includes four central angles CA61, CA62, CA63, and CA64 (relative to the rotation axis). The central angles CA61, CA62, CA63, and CA64 are equal. Each of the central angles CA61, CA62, CA63, and CA64 covers the three color blocks R, G and B. - In the embodiment, the arrangement logic of the filter blocks of the
color wheel 6 is similar to that of thecolor wheel 1. A difference therebetween is that the three color blocks R, G and B are arranged by four times on thecolor wheel 6. The other structural features of thecolor wheel 6 are the same as thecolor wheel 1. For example, the adjacent edges of the central angles CA61, CA62, CA63 and CA64 (i.e. the junctions thereof) and the adjacent edge of any two adjacent filter blocks 61-68 (i.e. the junctions thereof) are staggered. For example, the adjacent edge CA6 a of the central angles CA61 and CA63 does not align with the junction of the filter blocks 61 and 62 and the junction of the filter blocks 61 and 68. The adjacent edge CA6 b of the central angles CA61 and CA62 does not align with the junction of the filter blocks 62 and 63 and the junction of the filter blocks 63 and 64. The adjacent edge CA6 c of the central angles CA62 and CA63 does not align with the junction of the filter blocks 64 and 65 and the junction of the filter blocks 65 and 66. The adjacent edge CA6 d of the central angles CA63 and CA64 does not align with the junction of the filter blocks 66 and 67 and the junction of the filter blocks 67 and 68. For other descriptions about thecolor wheel 6, please refer to the relevant descriptions of thecolor wheel 1 and variations thereof, which will not be described in addition. Furthermore, in the embodiment, in logic, thecolor wheel 6 has Y physical filter blocks. Thecolor wheel 6 thereon defines X color blocks (corresponding X light colors respectively) which are arranged in the annular direction 60 a by repeating (N- 1 ) times. Each filter block is formed by one or more of one of the X defined color blocks. Therefore, thecolor wheel 6 can provide light of X light colors in each arrangement. Therein, X is equal to 3, N is equal to 4, Y is equal to 8, and X, N and Y satisfy the following equation: (X×N)−N=Y. - Those skilled in the art will readily observe that numerous modifications and alterations of the device and method may be made while retaining the teachings of the invention. Accordingly, the above disclosure should be construed as limited only by the metes and bounds of the appended claims.
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CN116165834A (en) * | 2021-11-24 | 2023-05-26 | 中强光电股份有限公司 | Wavelength conversion element and projector |
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JP2005326678A (en) * | 2004-05-14 | 2005-11-24 | Fujinon Corp | Color wheel |
JP2006017801A (en) * | 2004-06-30 | 2006-01-19 | Olympus Corp | Light source device and image projecting device |
EP1615449A3 (en) * | 2004-07-05 | 2006-10-25 | Thomson Licensing | Sequential colour display device |
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CN100526031C (en) * | 2005-09-16 | 2009-08-12 | 鸿富锦精密工业(深圳)有限公司 | Color wheel lens cutting process and assembling process |
JP2007101791A (en) * | 2005-10-03 | 2007-04-19 | Plus Vision Corp | Color wheel apparatus |
CN101750860B (en) * | 2008-12-11 | 2011-10-26 | 中强光电股份有限公司 | Light source module suitable for projective device |
CN101929637A (en) * | 2009-06-22 | 2010-12-29 | 中强光电股份有限公司 | Illumination system and illumination control method |
JP6439391B2 (en) * | 2014-11-06 | 2018-12-19 | 株式会社リコー | Light source device and projection display device |
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US20130003368A1 (en) * | 2011-06-29 | 2013-01-03 | Appotronics Corporation Limited | Multicolor illumination device using multiple light sources and a moving plate with wavelength conversion materials |
US20140176914A1 (en) * | 2012-12-20 | 2014-06-26 | Juergen Mueller | Lighting Device Comprising Pump Light Source, Phosphor Arrangement and Filter Arrangement |
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